KR20200110324A - Chromium tannery - Google Patents

Abstract

The present invention relates to certain chromium tanning agents and to their use in the tanning of skins and furs and to the leathers and felts obtainable thereby. The invention further relates to a novel process for obtaining a protein-shielding chromium tanning agent according to the invention from chromium- and collagen-containing materials, in particular wastes derived from the manufacture of leather, such as, for example, leather splitting. will be. This allows the recycling of chromium-containing wastes derived from leather manufacture, significantly reducing the amount of these wastes, providing significant economic, environmental and logistical advantages.

Description

Chromium tannery

The present invention relates to certain chromium tanning agents, to a process for their preparation and also to their use in tanning of rawhide and hide and to the resulting leathers and felts.

In the manufacture of leather, when adjusting the thickness, known as shaving, small leather split scraps mainly made of collagen material are obtained. When the leather has been pre-tanned with a chromium tanning agent, the tanned leather in a still wet state, also referred to as wet blue, will not only contain collagen, but also in an oxidation state (III) of about 2 to 6 wt %, usually Contains chromium.

Chromium (III) compounds present in professionally tanned leather are considered harmless from a health standpoint, but toxic or carcinogenic chromium (VI) compounds can be formed due to improper tanning or insufficient post-treatment of the leather or split crumbs. have.

Chromium tanning represents the most widely used tanning method, resulting in large amounts of chromium-containing leather splitting waste (approximately 17,000 t per year in Germany alone). Separating the protein and chromium components, and especially reusing the chromium fraction, is an expensive and complex task, so it is often uneconomical to fully recycle large amounts of waste, so the entire leather split scraps are disposed of and landfilled as special waste. Or pressed to form a bonded leather material, or incinerated in a controlled environment, which is harmful to the environment. Moreover, in this process, a large amount of collagen is lost, which may be used for cosmetics, medicines and nutrients for humans and animals, unless contaminated by chromium.

Conventional methods of separating proteins and chromium include the decomposition of the skin split debris by using acids or bases and/or by using microbial or enzymatic digestion by heating, these steps typically being taken from one another in complex multi-step operations. Are combined.

Generally speaking, basic hydrolysis, possibly combined with enzymatic hydrolysis, of leather splitting crumbs, as disclosed for example in DE4238979 A1, is an economically more important component, protein fraction, in the first stage of chromium -Has the advantage that it can be recovered in a free form, in which case the protein fraction obtained as gelatin has a chromium content of less than 0.1 ppm.

In contrast to this, in the case of acidic treatment, chromium is first separated and removed for the purpose of obtaining a protein fraction that does not contain chromium as much as possible. The problem in this case is that a relatively high proportion of chromium still remains in the collagen even after one treatment with an acidic chromium splitting crumb. Therefore, in the literature [Ferreira (Waste Management, 2010, 30, pp. 1091-1100)], there is a method that can recover only 55 to 60% of chromium by one treatment with sulfuric acid over a very long treatment time of 3 to 5 days. It is described. The remaining protein residues have a high proportion of chromium (40-45%) and toxic Cr(VI) compounds that cannot be disposed of through landfill by this treatment. As in the case of basic hydrolysis, in order to achieve substantial removal of chromium from the leather for the purpose of rational reuse of the protein fraction, many steps of treatment with acid are required, but in the acid solution formed, the fraction of destructive protein in the solution This becomes higher and higher and the concentration of chromium steadily decreases, making it more difficult to reuse. However, the entire operation becomes uneconomical due to the numerous acidic extraction steps required to reduce the chromium content of the protein fraction to levels usable for cosmetics, pharmaceuticals or nutrients for humans and animals.

In US 2005/0069472 A, the chromium split crumb is completely acidic hydrolyzed and the obtained chromium hydrolyzate is used as a tanning agent. However, in the example described, less than half of the chromium used is bound during tanning. As a result of complete hydrolysis of the split crumbs, a protein fraction cannot be obtained.

Currently, the most used method for separating proteins and chromium is the digestion of leather splitting debris with a base, optionally combined with microbial and/or enzymatic digestion by heating (e.g., Cabeza, LF, JALCA, 1998, 93, pp. 83-97). In the process described above, the leather split crumbs are first decomposed into magnesium oxide to obtain a gelatin as well as a chromium-containing residue called chromium cake. These cakes are further digested with enzymes to obtain collagen hydrolysates and chromium-containing solids. The problem in this case is that the chromium cake cannot be used directly as a tanning agent since it still contains a significant amount of protein that prevents the tanning effect. To remove this destructive protein content, in the prior art the chromium cake was first dissolved in sulfuric acid, and then in two additional steps, the pH was raised with sodium hydroxide to remove the chromium-containing residue from the protein fraction. . Each of these steps requires a filtration step, which not only produces a large number of proteinaceous waste products that cannot be reused, but also ultimately results in purified chromium(III) sulfate which can be used later and subsequently as a chromium tanning agent. Is created. The large number of process steps and the high fraction of proteinaceous waste that cannot be reused interfere with the economics of the process.

Another process for post-treating chromium cakes is disclosed in CN103014191A. In this process, as in the example above, after basic hydrolysis of split crumbs and removal of the protein, the chromium cake is dissolved in a strong acid, and then toxic and mutagenic Cr(VI) compounds are added, so that the proteinaceous components still present. Is removed by oxidation. Subsequently, a reducing agent is added to remove excess Cr(VI). If the chromium (VI) residue is not completely removed, this step must be carefully monitored as the chromium tanners recovered in this way cannot be used again. The thus recovered, substantially protein-free chromium tanning agent can subsequently be used as a chromium tanning agent. However, with regard to the implementation of the process, the use of Cr(VI) compounds is practically undesirable as it imposes stringent safety requirements on manufacturing facilities and personnel.

It is therefore an object of the present invention to provide a simple method for recycling of materials containing chromium and collagen, more particularly leather splitting scraps, which avoids the above drawbacks of the prior art.

Chromium tanning agents can be used directly, for example in the form of chromium salts or solutions thereof, but in many applications, as organic acids, for example aliphatic or aromatic carboxylic acids, such as acetic acid, or salts thereof It is advantageous to mask the tanning agent. Examples of such chromium tanning agents are described in DE1230170B. Masked chromium tanning agents are known to be suitable for milder and safer tanning and also retanning of leather, and to have relatively good stability against alkalis. As a result, the risk of developing chromium spots in the neutralizing stage of tanning is reduced. The obtained leather has a better plump feel and a softer feel. The grain appearance is particularly fine and smooth, and the degree of freedom from puckering is increased. Moreover, the color of the leather is, for example, as disclosed in (Bibliothek des Leders, Volume 3, "Gerbmittel, Gerbung, Nachgerbung" [Tans, Tannage, Retanning], Kurt Faber, 2nd edition, 1990, pages 79-80). , More intense and more uniform. Due to the shielding, the utilization of these tanners at the same final pH when tanning is actually slightly lower than that of the unshielded chromium tanners, but since some of the shielded tanners have better stability against alkalis, tanning. Higher final pH levels can also be used during, so the consumption achieved is comparable to that achieved with an unmasked chromium tanner, but the leather quality is better.

Better stability to alkali can be measured by determining the flocculation point, which is expressed as percent basicity.

The basicity of chromium tanning agents is a measure of the number of hydroxyl groups per chromium ion and is itself known to the skilled person. The description of the term and the method of determining the basicity can be found in, for example, Bibliothek des Leders, Volume 3, "Gerbmittel, Gerbung, Nachgerbung" [Tans, Tannage, Retanning], Kurt Faber, 2nd edition, 1990, pages 73-75. and pages 　283-285).

To determine the agglomeration point of the masked chromium tannery, the amount of base is measured until the point of aggregation is reached, the molar amount of hydroxide ions produced by the base is divided by three times the molar amount of chromium ions, and the used Add to the basicity value of the chromium tannery. In this case, officially, at the point of aggregation, at a basicity of 33.3% there is one hydroxide ion per chromium ion, at a basicity of 66.6% there is two hydroxide ions per chromium ion, and 100% In basicity, there are three hydroxide ions per chromium ion. Because of the masking, in some cases a higher amount of base is required to allow precipitation to occur, so the basicity value may well exceed 100%.

The amount of base required to change the basicity by 1% is known to the skilled person, and the amount corresponds to 20.9 mg of Na ₂ CO ₃ per 1000 mg of chromium oxide, calculated as, for example, Cr ₂ O ₃ (literature (See Bibliothek des Leders, Volume 3, "Gerbmittel, Gerbung, Nachgerbung" [Tans, Tannage, Retanning], Kurt Faber, 2nd edition, 1990, page 75).

The agglomeration point, calculated as Cr ₂ O _3, was to prepare an aqueous solution (100 ml) of chromium tanning agent containing 2.6 wt% chromium oxide and continued stirring it at room temperature for 8 h until permanent aggregation was evident. And it is determined by titrating it with a 1.5 mol sodium carbonate aqueous solution (dropping rate of 10 ml/min).

Since the aggregation point depends not only on the initial concentration of chromium oxide in the measured solution, but also on the stirring time after setting the chromium oxide content, in the case of the present invention, aggregation is exactly 8 hours after setting the chromium oxide content of the solution to 2.6%. The point is measured and the solution is kept stirring at room temperature.

This advantageous effect of masking is particularly evident in the range of the aggregation point of 66-150% basicity. Above 150%, the skilled artisan says that overshielding has occurred, at which time the binding of the chromium tanning agent to the collagen is very much reduced or not present at all, which means that the tanning effect is greatly reduced or no longer present. At the point of aggregation of a basicity of 65% or less, the shielding is no longer effective.

Therefore, a further object of the present invention was to provide a masked chromium tanning agent obtainable in an efficient and economical manner at least in part from recycled materials containing chromium and collagen.

To the present invention, surprisingly, in order to achieve the object of the present invention, it is not necessary to specifically remove the protein fraction as well as possible from the insoluble residues obtainable in the basic hydrolysis of substances containing chromium and collagen, instead Eh, it has been found that by setting the point of aggregation to a value in the range of 66 to 150% basicity, the protein fraction can be successfully used to mask chromium tanning agents.

In this case, the point of aggregation is 1 selected from the group of chromium tanning agents, in particular chromium (III) compounds, preferably chromium (III) oxides, chromium (III) hydroxides, chromium (III) halides and chromium (III) sulfates. It can be set by adding more than one kind of compound, more preferably basic chromium(III) sulfate.

Therefore, the subject of the present invention is a method for producing a protein-shielding chromium tanning agent comprising the following method steps:

-Basic hydrolysis of at least a portion of the collagen fraction of a material containing chromium and collagen,

-Removing insoluble components of the material obtained in hydrolysis,

-dissolving the insoluble component removed in the previous step by lowering the pH to a value of 1 to 6, preferably 1 to 3, more preferably 2.5,

-Adding a chromium (III) compound to the solution until the solution obtained in the previous step has an aggregation point in the range of 66 to 150% basicity.

In a preferred embodiment, the latter two process steps are combined by adding an acidic chromium(III) compound to lower the pH. Suitable acidic chromium(III) compounds exhibit a pH of less than 6.0, preferably less than 4.0 and most preferably less than 2.0 at room temperature when mixed with water in a 1:9 ratio. Preferably, a chromium compound selected from chromium(III) oxide, chromium(III) hydroxide, chromium(III) halide and chromium(III) sulfate, most preferably basic chromium(III) sulfate is used. By the way, the name of the latter is derived from the basicity of the chromium tanning agent, not the pH of its aqueous solution below 7. Other acidic chromium(III) compounds that can be used in the present invention are obtained by separating and separating the chromium residue remaining in the tanning liquid at a high pH after the tanning process and then dissolving at a lower pH.

In this case, the protein-shielding chromium tanning agent is a combination of chromium tanning agents, in particular chromium (III) compounds, such as chromium (III) oxide, chromium (III) hydroxide, chromium (III) halides and chromium (III) sulfates, and collagen. It is understood to be a mixture of protein fractions obtainable by basic hydrolysis.

The added chromium (III) compound is preferably chromium (III) oxide, chromium (III) hydroxide, chromium (III) halide and/or chromium (III) sulfate or mixtures of these substances, more preferably basic chromium ( III) It is a sulfate salt.

The term “material containing chromium and collagen” in its broadest definition includes all materials containing chromium and containing collagen; Chromium-containing leather is preferred, and chromium-containing leather splitting shavings are particularly preferred.

The lowering of the pH is achieved by adding an acid, preferably an inorganic acid, more preferably sulfuric acid and/or hydrochloric acid, very preferably sulfuric acid.

Chromium-containing leather is understood to include raw hides and hides tanned with chromium tanning agents, wherein the shrinkage temperature of the typically tanned rawhide material allows for subsequent processing by mechanical work and mechanical and thermal exposure, e.g. For example, it is high enough to at least achieve hydrothermal stabilization of the rawhide material to prevent damage caused by frictional heat during splitting.

The chromium oxide content in the used material containing chromium and collagen is typically less than 10 wt%, more preferably 7 wt%, based on the total mass of the dried material containing chromium and collagen at a residual moisture content of 10 wt%. %, very preferably less than 5 wt%.

Basic hydrolysis refers to a decrease in the molecular weight of collagen under basic conditions. Basic hydrolysis is typically accomplished using oxides or hydroxides of alkali metals and/or alkaline earth metals, preferably oxides or hydroxides of sodium, potassium and/or magnesium, more preferably magnesium oxide. In this case, the material obtained typically comprises a protein having a weight-average molecular weight Mw of less than 310 Daltons, preferably less than 280 Daltons, more preferably less than 250 Daltons. In contrast, proteins obtained from acidic hydrolysis of substances containing chromium and collagen have a weight-average molecular weight M _{w of} at least 320 Daltons.

As a result of attempting to use a protein obtained by acidic hydrolysis of chromium split crumbs instead of a protein obtainable by basic hydrolysis of a material containing chromium and collagen in the present invention, a satisfactory tanning effect was not obtained. It was found that the lower molecular mass of the protein obtained by the basic hydrolysis of collagen enables a higher penetration ability for some of the chromium tanning agents produced using it, thereby achieving a better tanning effect in the cross section of the rawhide. Is estimated.

In one preferred embodiment, the protein-masked chromium tanning agent obtainable by the method is obtained in the form of an aqueous solution. In a further embodiment, these solutions are converted to powders or granules by drying, preferably spray drying.

Therefore, a further subject of the present invention is a protein-shielding chromium tanning agent comprising a protein obtained by basic hydrolysis of chromium and collagen in oxidation state 3, wherein the chromium tanning agent is agglomerated in the range of 66 to 150% basicity. Has a point.

Preferably, the protein as well as some of the chromium in the +3 oxidation state are derived from insoluble or poorly soluble residues obtained from basic hydrolysis of materials containing chromium and collagen. The other part of the chromium in the +3 oxidation state in this case is the chromium(III) compound, preferably chromium(III) oxide, chromium(III) hydroxide, chromium(III) halide and chromium added to these residues. (III) sulfates or mixtures of these substances, more particularly derived from chromium tanning agents in the form of basic chromium(III) sulfates.

The chromium oxide content of the protein-shielding chromium tannery calculated as Cr ₂ O ₃ is typically greater than 5 wt %, preferably greater than 8 wt %, more preferably 10 to 26 wt %. This chromium oxide content is based on the total weight of the dried protein-shielding chromium tanning agent, having a residual water content of 10 wt% or less, preferably 5 wt%.

The amount of protein obtained by basic hydrolysis of collagen in the protein-shielding chromium tanning agent is typically 2 to 50 wt%, preferably 4 to 25 wt%, more preferably 5 to 12 wt%. This protein content is based on the total weight of the dried protein-shielding chromium tanning agent having a residual water content of 10 wt% or less, preferably 5 wt%.

The protein-masked chromium tanneries obtainable by this method typically have a basicity of 0 to 65%, preferably 4 to 55%, more preferably 9 to 40%.

The protein-shielding chromium tanning agent can be in the form of a powder, granule or aqueous solution.

A further subject of the invention is the use of protein-shielding chromium tanning agents in the tanning and/or retanning of leather or felt.

A further subject is a method of tanning and/or retanning leather or felt by treating rawhide or hide with the protein-shielding chromium tanning agent of the present invention.

Moreover, the invention also includes leather or felt obtainable by the method of the invention for tanning and/or retanning leather or felt.

Therefore, the present invention is advantageous in the recycling of materials containing chromium and collagen, more particularly leather manufacturing waste, such as, for example, leather splitting, which can be converted into an advantageous protein-shielding chromium tanning agent and returned to the tanning operation. It is very suitable for, allowing a significant reduction in the amount of chromium-containing waste during leather manufacturing, and offers significant advantages in terms of economy, environment and logistics.

Example

The following examples illustrate the invention in more detail and are not intended to limit the invention at all.

Preparation of chromium tanning agent

The chromium-containing solution A used in the following examples is derived from a commercially operated facility for the basic processing of split flakes of chromium-tanned raw hides of cattle, in which residues containing chromium and collagen (chromium cake) are produced. Is created. After dissolving this residue with sulfuric acid, the pH is adjusted to 2.3. The solution has a basicity of 9.1% and the chromium oxide content of the solution, calculated as Cr ₂ O ₃ , is 3.6%. The solids content is 35%. The measured point of aggregation (for the solution diluted to have 2.6% chromium oxide) is 520% basicity.

The chromium tanning agent added in the examples, having a basicity of 33% and a chromium oxide content of about 26% calculated as Cr ₂ O ₃ , is a powdery basic chromium sulfate (Chromosal of Lanses Deutschland GmbH) ^® B). The point of aggregation measured for this solution diluted to have 2.6% chromium oxide is 62% basicity.

M1) Mixture of chromium solution A and basic chromium sulfate

In a stirred flask, 103 g of water and 247 g of basic chromium sulfate are added to 650 g of chromium-containing solution A. The solution is then heated to 80° C. and stirred at this temperature for 1 h.

The mixture has a basicity of 24% and contains 8.8% of chromium oxide calculated as Cr ₂ O ₃ . The aggregation point of the solution diluted to have 2.6% chromium oxide is 89% basicity.

M2) Mixture of chromium solution A and basic chromium sulfate

In a stirred flask, 505 g of water and 295 g of basic chromium sulfate are added to 200 g of chromium-containing solution A. The solution is then heated to 80° C. and stirred at this temperature for 1 h.

The mixture has a basicity of 30% and contains 8.4% of chromium oxide calculated as Cr ₂ O ₃ . The aggregation point of the solution diluted to have 2.6% chromium oxide is 72% basicity.

M3) Mixture of chromium solution A and basic chromium sulfate

In a stirred flask, 288 g of water and 412 g of basic chromium sulfate are added to 300 g of chromium-containing solution A. The solution is then heated to 80° C. and stirred at this temperature for 1 h.

The mixture has a basicity of 30% and contains 11.8% of chromium oxide calculated as Cr ₂ O ₃ . The aggregation point of the solution diluted to have 2.6% chromium oxide is 76% basicity.

M4) Mixture of chromium solution A and basic chromium sulfate

In a stirred flask, 155 g of water and 545 g of basic chromium sulfate are added to 300 g of chromium-containing solution A. The solution is then heated to 80° C. and stirred at this temperature for 1 h.

The mixture has a basicity of 31% and contains 15.2% of chromium oxide calculated as Cr ₂ O ₃ . The aggregation point of the diluted solution with 2.6% chromium oxide is 69% basicity.

Examples of practice with chromium tanning agent

Use Example 1: Tanning

The starting materials used include (small) felts with a thickness of approximately 1.8-2.0 mm, partitioned and weighed after liming. All the following amounts for the use of chemicals are based on this basis weight (felt weight).

After the usual manufacturing operations known to the person skilled in the art, 18% chromium tanning agent in solution form, prepared in Example M1, is added to the pickled felt and the treatment is carried out for 60 min. Subsequently, magnesium oxide is added as a slow acting alkalizing agent. As a result, the pH of the solution starts from 2.6 and rises until the final pH reaches 3.8 within 8 h after the addition of the chromium tanning agent. Likewise, the temperature initially rises from 20°C to 40°C. Table 1 shows the steps of the method of the invention for the production of semifinished leather products (wt% is based on the weight of the felt).

<Table 1>

After carrying out the method of the present invention, the leather semi-finished product is stored on a mount, dehydrated and split.

Wet blue has a shrinkage temperature above 100° C. and a Cr ₂ O ₃ content of 4.1%. The Cr ₂ O ₃ content of the residual suspension is 4.2 g/l.

It is noteworthy that the wet blue thus produced has particularly excellent plump feeling and soft touch. The silver appearance is particularly fine and smooth, and the absence of perkering is increased.

Use Example 2: Tanning

It is carried out as in Use Example 1, except that the final pH is 4.2.

Wet blue has a shrinkage temperature above 100° C. and a Cr ₂ O ₃ content of 4.4%. The Cr ₂ O ₃ content of the residual suspension is 2.1 g/l.

The wet blue thus prepared, despite the elevated final pH, exhibits no chromium precipitation and has an attractive blue color. The feeling of plumpness, texture, silver appearance, and absence of perkering are comparable to those of Use Example 1.

Use Example 3: Tanning

It was carried out as in Use Example 1 except that 14.5% of the chromium tanning agent prepared according to Example 3 was used. The final pH is 3.8.

Wet blue has a shrinkage temperature above 100° C. and a Cr ₂ O ₃ content of 4.3%. The Cr ₂ O ₃ content of the residual suspension is 2.7 g/l.

It is noteworthy that the wet blue thus produced has particularly excellent plump feeling and soft touch. The silver surface appearance is particularly fine and smooth, and the absence of perkering is increased.

Use Example 4: Tanning

It is carried out as in Use Example 3, except that the final pH is 4.1.

Wet blue has a shrinkage temperature above 100° C. and a Cr ₂ O ₃ content of 4.6%. The Cr ₂ O ₃ content of the residual suspension is 1.9 g/l.

The wet blue so produced, despite the increased final pH, shows no chromium precipitation and has an attractive blue color. It likewise has an excellent plump and soft feel. The silver surface appearance is particularly fine and smooth, and the absence of perkering is increased.

Comparative Example 1: Tanning

It is carried out as in Use Example 1, except that 6.5% basic chromium sulfate (Cromosal ^® B) is used.

The final pH is 3.8.

Wet blue has a shrinkage temperature above 100° C. and a Cr ₂ O ₃ content of 4.5%. The Cr ₂ O ₃ content of the residual suspension is 2.0 g/l.

The wet blue thus prepared has a greener color than the wet blue prepared using the chromium tanning agent of the present invention. Moreover, it is less plump and harder to the touch. The silver surface is rougher and the lack of perkering is lower.

Use Example 5: Retanning

The semi-finished leather split to have a thickness of 1.1 mm is treated by conventional manufacturing operations known to the skilled person, such as washing, followed by mixing with 12% chromium tanning agent in solution form, prepared in Example M1, and processing Is carried out for 60 min. Then slowly neutralizing Syntan (Tanigan ^® PAK from Lanses Deutschland GmbH) and a substance having alkaline activity are added, and the pH is raised to 5.1.

The typical retanning formulation was then applied for the manufacture of furniture crust leather.

Table 2 shows the steps of the method of the present invention for producing crust leather (wt% is based on split weight).

<Table 2>

It is noteworthy that the crust leather produced in this way has a particularly good plump feel and soft feel. The silver surface appearance is particularly fine and smooth, and the absence of perkering is increased. The color of the crust leather is particularly intense and uniform.

Claims (15)

It is a protein-shielding chromium tanning agent comprising a protein obtained by basic hydrolysis of chromium and collagen in oxidation state 3, wherein the chromium tanning agent has a flocculation point in the range of 66 to 150% basicity. And the agglomeration point is to prepare an aqueous solution of chromium tanning agent containing 2.6 wt% of chromium oxide calculated as Cr ₂ O ₃ and continue stirring the solution at room temperature for 8 h until permanent aggregation becomes apparent. Protein-shielding chromium tanning agent, which was determined by titration with a 1.5 molar aqueous sodium carbonate solution. The protein-shielding chromium tanning agent according to claim 1, wherein the chromium oxide content calculated as Cr ₂ O ₃ is greater than 5 wt%, preferably greater than 8 wt%, more preferably 10 to 26 wt%. The protein-shielding according to claim 1 or 2, wherein the amount of protein obtained by hydrolysis of collagen is 2 to 50 wt%, preferably 4 to 25 wt%, more preferably 5 to 12 wt%. Chromium tanning agent. Protein-shielding chromium tanning agent according to any one of claims 1 to 3, having a basicity of 0 to 65%, preferably 4 to 55%, more preferably 9 to 40%. The protein-shielding chromium tanning agent according to any one of claims 1 to 4, which is present in the form of a powder, granules or aqueous solution. A method of preparing a protein-shielding chromium tanning agent comprising the following method steps:
-Basic hydrolysis of at least a portion of the collagen fraction of a material containing chromium and collagen,
-Removing insoluble components of the material obtained in hydrolysis,
-dissolving the insoluble component removed in the previous step by lowering the pH to a value of 1 to 6, preferably 1 to 3, more preferably 2.5,
-Adding a chromium (III) compound to the solution until the solution obtained in the previous step has an aggregation point in the range of 66 to 150% basicity. The chromium tanning agent according to claim 6, wherein the added chromium tanning agent is at least one chromium (III) compound, preferably chromium (III) oxide, chromium (III) hydroxide, chromium (III) halide and chromium (III) sulfate, or these substances. Chromium (III) compounds selected from mixtures of, more preferably basic chromium (III) sulfate. The method according to claim 6 or 7, wherein the material containing chromium and collagen comprises chromium-containing leather, preferably chromium-containing leather splitting shavings. Process according to any of claims 6 to 8, wherein the lowering of the pH is achieved by addition of an acid, preferably an inorganic acid, more preferably sulfuric acid and/or hydrochloric acid, more preferably sulfuric acid. . 10. The method according to any of claims 6 to 9, wherein the basic hydrolysis is carried out in an oxide or hydroxide of an alkali metal and/or alkaline earth metal, preferably an oxide or hydroxide of sodium, potassium and/or magnesium, more preferably a hydroxide. Which is carried out using potassium. The method according to any one of claims 6 to 10, wherein the masked chromium tanning agent has a basicity of 0 to 65%. The method according to any one of claims 6 to 11, wherein after the chromium tanning agent is added, drying is preferably carried out by spray drying, and the protein-shielding chromium tanning agent is obtained in powder form or as granules. . The method according to any one of claims 6 to 12, wherein the method step comprising lowering the pH and the method step comprising adding a chromium (III) compound, the pH is increased by adding an acidic chromium (III) compound. The method being combined into a method step comprising lowering. Use of a protein-shielding chromium tanning agent according to any one of claims 1 to 5 for tanning or retanning leather. A method of tanning and/or retanning leather or felt by treating rawhide or hide with a protein-shielding chromium tanning agent according to claim 1.